Your search keyword '"Ripoll, Marisol"' showing total 4 results

1. Chiral active systems near a substrate: Emergent damping length controlled by fluid friction.

Author

Mecke, Joscha, Gao, Yongxiang, Gompper, Gerhard, and Ripoll, Marisol

Subjects

FLUID friction, ROTATIONAL diffusion, COLLOIDS, CAPABILITIES approach (Social sciences), FLUID control

Abstract

Chiral active fluids show the emergence of a turbulent behaviour characterised by multiple dynamic vortices whose maximum size varies for each experimental system, depending on conditions not yet identified. We propose and develop an approach to model the effect of friction close to a surface in a particle based hydrodynamic simulation method in two dimensions, in which the friction coefficient can be related to the system parameters and to the emergence of a damping length. This length is system dependent, limits the size of the emergent vortices, and influences other relevant system properties such as the actuated velocity, rotational diffusion, or the cutoff of the energy spectra. Comparison of simulation and experimental results of a large ensemble of rotating colloids sedimented on a surface shows a good agreement, which demonstrates the predictive capabilities of the approach, which can be applied to a wider class of quasi-two-dimensional systems with friction. The dynamics of chiral active fluids is characterised by a multitude of interacting dynamic vortices whose maximum size varies for each system. Here we show how the friction induced by the substrate is related to a damping length which is ultimately responsible of limiting the maximum size of the vortices. [ABSTRACT FROM AUTHOR]

Published

2024

2. Simultaneous emergence of active turbulence and odd viscosity in a colloidal chiral active system.

Author

Mecke, Joscha, Gao, Yongxiang, Ramírez Medina, Carlos A., Aarts, Dirk G.A.L., Gompper, Gerhard, and Ripoll, Marisol

Subjects

TURBULENCE, MEASUREMENT of viscosity, BULK viscosity, VORTEX motion, COMPRESSIBILITY, LARGE eddy simulation models

Abstract

Active fluids display collective phenomena such as active turbulence or odd viscosity, which refer to spontaneous complex and transverse flow. The simultaneous emergence of these seemingly separate phenomena is here reported in experiment for a chiral active fluid composed of a carpet of standing and spinning colloidal rods, and in simulations for synchronously rotating hard discs in a hydrodynamic explicit solvent. Experiments and simulations reveal that multi-scale eddies emerge, a hallmark of active turbulence, with a power-law decay of the kinetic-energy spectrum, a feature of self-similar dynamics. Moreover, the particles are dragged to the centre of the vortices, a telltale sign of odd viscosity. The weak compressibility of the system enables an explicit measurement of the odd viscosity in bulk via the relation between local vorticity and excess density. Our findings are relevant for the understanding of biological systems and for the design of microrobots with collective self-organized behavior. The investigation of a chiral active fluid composed of a carpet of standing and spinning colloidal rods, combined with simulations for synchronously rotating hard discs in a hydrodynamic explicit solvent reveals here the simultaneous occurrence and relation of two seemingly separate phenomena: active turbulence and odd viscosity. [ABSTRACT FROM AUTHOR]

Published

2023

3. Self-phoretic Brownian dynamics simulations.

Author

Roca-Bonet, Sergi and Ripoll, Marisol

Subjects

*THERMOPHORESIS, *COLLECTIVE behavior, *DIMERS, *SWIMMERS, *BROWNIAN motion

Abstract

A realistic and effective model to simulate phoretic Brownian dynamics swimmers based on the general form of the thermophoretic force is here presented. The collective behavior of self-phoretic dimers is investigated with this model and compared with two simpler versions, allowing the understanding of the subtle interplay of steric interactions, propulsion, and phoretic effects. The phoretic Brownian dynamics method has control parameters which can be tuned to closely map the properties of experiments or simulations with explicit solvent, in particular those performed with multiparticle collision dynamics. The combination of the phoretic Brownian method and multiparticle collision dynamics is a powerful tool to precisely identify the importance of hydrodynamic interactions in systems of self-phoretic swimmers. [ABSTRACT FROM AUTHOR]

Published

2022

4. Collective behavior of thermophoretic dimeric active colloids in three-dimensional bulk.

Author

Wagner, Martin, Roca-Bonet, Sergi, and Ripoll, Marisol

Subjects

COLLECTIVE behavior, DIMERS, SOLVENTS, SWIMMERS

Abstract

Colloids driven by phoresis constitute one of the main avenues for the design of synthetic microswimmers. For these swimmers, the specific form of the phoretic and hydrodynamic interactions dramatically influences their dynamics. Explicit solvent simulations allow the investigation of the different behaviors of dimeric Janus active colloids. The phoretic character is modified from thermophilic to thermophobic, and this, together with the relative size of the beads, strongly influences the resulting solvent velocity fields. Hydrodynamic flows can change from puller-type to pusher-type, although the actual flows significantly differ from these standard flows. Such hydrodynamic interactions combined with phoretic interactions between dimers result in several interesting phenomena in three-dimensional bulk conditions. Thermophilic dimeric swimmers are attracted to each other and form large and stable aggregates. Repulsive phoretic interactions among thermophobic dimeric swimmers hinder such clustering and lead, together with long- and short-ranged attractive hydrodynamic interactions, to short-lived, aligned swarming structures. [ABSTRACT FROM AUTHOR]

Published

2021